Calculating machine



y 6, 1958 R. E. BOYDEN ET AL 2,833,466

CALCULATING MACHINE, INCLUDING ORDINALLY SHIFTABLE FACTOR STORAGE AND VALUE ENTRY CONTROL DEVICES Filed Nov. 16, 1955 17 Sheets-Sheet 1 /7 S R 20*; L:

INVENTORJ, l Roberf EBOHCZEH, Paul BJohnson,

R. E. BOYDEN ET AL May 6, 1958 CALCULATING MACHINE, INCLUDING ORDINALLY SHIFTABLE FACTOR STORAGE AND VALUE ENTRY CONTROL DEVICES l7 Sheets-Sheet, 2

Filed Nov. 16, 1953 BLC/IFZS f) R. E. BOYDEN ET AL 2,833,466

INCLUDING ORDINALLY SHIFTABLE FACTOR STORAGE AND VALUE ENTRY CONTROL DEVICES May 6, 1958 CALCULATING MACHINE Filed Nov. '16, 1955 1'7 Sheets-Sheet 3 D MFL INVENTORJ,

Robert fiBqyden, &Ch flu) 'Paulflifohnson, r15 r1 0%/ HTTOHNEY.

y 1958 R E. BOYDEN ET AL 2,833,466

CALCULATING MACHINE INCLUDINGORDINALLY SHIFTABLE FACTOR STORAGE AND VALUE ENTRY CONTROL DEVICES Filed Nov. 16, 1953 1'7 Sheets-Sheet, 4

ATTORNEY.

6 6 9? 8h 2m F I H s V. ME L Am Tm E D GN Nm EDE 0mm mm OIT B 5 Ram mF G N I T A L U m o A 5C 9 1 6 Y M ENTRY CONTROL DEVICES l7 Sheets-Sheet. 5

Filed Nov. 16, 1953 RoberT E Bgyden A iabg ghnson J fl? 0 Q HTTORNEY.

May 6, 1958 CALCULATING MACHINE; INCLUDING ORDINALLY SHIFTABLE FACTOR STORAGE AND VALUE ENTRY CONTROL DEVICES 17 Sheets-Sheet. 6

Filed Nov. 16, 1953 E WFL x x E- mam wm Fla-4 m Mm 3% N 0 0 mi WE Bf r u Mu o s R H 6 N n P. am

HT'TORNEY.

2,833,466 CALCULATING MACHINE, INCLUDING ORDINALLY SHIFTABLE May 6, 1958 R. E. BOYDEN ET AL FACTOR STORAGE AND VALUE ENTRY CONTROL DEVICES Filed Nov. 16, 1953 17 Sheets-Sheet. 7

INVENTORJ, RoberT ifia gden, &Ch r9 P5513 585. Johnson,

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HTTORNEY.

y 1953 R. E. BOYDEN ET AL 2,833,465

CALCULATING MACHINE, INCLUDING ORDINALLY SHIFTABLE FACTOR STORAGE AND VALUE ENTRY CONTROL DEVICES 1'7 Sheets-Sheet. 8

Filed NOV. 16, 1953 INVENTORJ, im ,3 Johnson,

Robert E 130 -Peg ATTORNEY. W

y 6, 1958 R. E. BOYDEN ET AL 2,833,466

CALCULATING MACHINE, INCLUDING ORDINALLY SHIFTABLE FACTOR STORAGE AND VALUE ENTRY CONTROL DEVICES l7 Sheets-Sheet 9 Filed NOV. 16, 1953 INVEN TORJ,

mm d T M w. BU. FMB/ fi m at? m a 8L Chris 19. C/zr/ ATTORNEY.

y 1958 R. E. BOYDEN ET AL 2,833,466

CALCULATING MACHINE, INCLUDING ORDINALLY SHIFTABLE FACTOR STORAGE AND VALUE ENTRY CONTROL DEVICES 1'7 Sheets-Sheetv 10 Filed Nov. 16, 1953 MHMFL INVENTORJ,

Roberi'fifioyden, uh N m fig??? m W V v mMmE 23% I w L May 6, 1958 Filed Nov. 16, 1953 R. E. BOYDEN ET AL 2,833,466 CALCULATING MACHINE, INCLUDING ORDINALLY SHIFTABLE FACTOR STORAGE AND VALUE ENTRY CONTROL DEVICES l7 Sheets-Sheet, 11

IlllllllllllllllllllllllllllllllIllllllIlllllllIIIIIIIIIIIIIIIIIllllllllllllllllll] In TINVENTORS, Rober iBo yderL, L E] PaulBJohnson,

fiTTORNEY.

y 1958 R. E. BOYDEN ET AL 2,833,466

CALCULATING MACHINE, INCLUDING ORDINALLY SHIFTABLE FACTOR STORAGE AND VALUE ENTRY CONTROL DEVICES Filed Nov. 16, 1953 17 Sheets-Sheet 12 FIIiEI INVENTORJ, RobrT E.,B0 qden,

?au1 BJohnson,

2 sham/m, n by BOYDEN ET AL 2,833,466 CALCULATING MACHINE, INCLUDING ORDINALLY SHIFTABLE FACTOR STORAGE AND VALUE ENTRY CONTROL DEVICES May 6, 1958 Filed NOV. 16, 195?) 1'7 Sheets-Sheet 13 R. E. BOYDEN ETAL 2,833,466 CALCULATING MACHINE, INCLUDING ORDINALLY SHIFTABLE FACTOR STORAGE AND VALUE ENTRY CONTROL DEVICES May 6, 1958 17 Sheets-Sheet 14 Filed Nov. 16, 1953 IIIlfIIIIII IIIIIIIIIIIIIIIIIIIII I14 'IIIIIIA'A INVENTORJ, Roberf E..Bogden,

ATTORNEY.

BOYDEN ET AL CALCULATING MACHINE, INCLUDING ORDINALLY SHIFTABLE May 6, 1958 FACTOR STORAGE AND VALUE ENTRY CONTROL DEVICES 17 Sheets-Sheet. 15

Filed NOV. 16, 1953 y 1958 E. BOYDEN ET AL 2,833,466

CALCULATING MACHINE, INCLUDING ORDINALLY SHIFTABLE FACTOR STORAGE AND VALUE ENTRY CONTROL DEVICES Filed Nov. 16, 1953 17 sheet heet. 6

i l [UL INVENTOR-fl- Robert Efio yden P l .Jh skim; H.(/19%fy ATTORNEY.

R. E. BOYDEN ETAL 2,833,466 CALCULATING MACHINE, INCLUDING ORDINALLY SHIFTABLE FACTOR STORAGE AND VALUE ENTRY CONTROL DEVICES May 6, 1958 17 Sheets-Sheet 17 Filed Nov. 16, 1953 WV U L INVENTORJ, Roberl' E Bqyden,

Pui lgugg hnson "0/? I HT'I'ORNEY.

2 5 w -28 2% 253 M ESQ $3M -QMEBM m5 grss 5 3; Chm/19% nited States Patent ffice 2,833,466 Patented May 6, 1958 CALCULATHNG MACHINE, INCLUDING ORDI- NALLY SHIFTABLE FACTOR STORAGE AND VALUE ENTRY CON'E'RQL DEVICES Robert E. Boyden, San Gabriel, Paul B. Johnson, Los Angeles, and Chris A. Christofi, San Gabriel, Calirl, izssignors to Clary Corporation, a corporation of Caliorma Application November 16, 1953, Serial No. 392,190

10 Claims. (Cl. 235-60) This invention relates to cyclically operable calculating machines of the type capable of performing the four cardinal types of calculation, i. e., addition, subtraction, multiplication and division, and including devices for recording the factors and results of such calculations.

Generally speaking, mechanical calculating machines capable of performing such calculations as multiplication and division embody transversely shiftable registers, transversely shiftable differential actuators or transversely shiftable amount entry devices in order to facilitate the calculating process and reduce to a minimum the number of cycles required to solve different problems, wherein an active factor, such as a multiplier factor, embodies a plurality of digits.

In the foregoing types of calculating machines it was heretofore necessary to increase the width of the machine, or at least certain portions thereof materially beyond the width of the actuator section in order to permit relative shifting of the register and actuators or relative shifting of the amount entry devices and the actuators. For example, ten key amount entry devices have been employed for effecting shifting of an amount relative to the actuators. Such entry devices included a pin carriage or the like having selectively settable stop elements positioned by a group of ten keys ranging in value from O to 9, such stop elements being effective to differentially control the extent of movement of aligned actuators. The pin carriage is shiftable in a step-by-step movement across the actuators. In order to permit traverse of the pin carriage across a whole group of actuators and yet maintain the machine within acceptable limits of width, the actuators must be spaced very close to each other, thus imposing a considerable hardship from the standpoint of restrictions in design and service due to the close spacing of the parts. For example, lateral tolerances of the parts such as amount entry device, accumulator, etc., must be reduced and maintained correspondingly.

Therefore, it is a principal object of the present invention to provide, in a mechanical calculating machine, a relatively shiftable amount entry device and a group of diifcrential actuators controlled thereby without extending the width of the machine materially beyond the width of the actuator group.

Another object of the invention is to render a calculating machine of the above type very flexible in operation and capable of solving a wide variety of problems.

Another object is to provide a single manipulable control member to both selectively position an amount entry device relative to differential actuators controlled thereby and to control operation of the machine.

Another object is to provide a single manipulable control member to both selectively position an amount entry device relative to diiferential actuators controlled thereby and to selectively control additive and subtractive operations of the machine.

Another object is to provide a calculating machine capable of multiplying and dividing and recording the factors and results of such calculations in sequence without recording the intermediate results or factors of such calculations.

A further object is to provide a recording-calculating machine capable of recording the factors and results of multiplication, etc., about a 1. ed decimal point position.

A further object is to modify a recording, adding and subtracting machine to facilitate solving problems in multiplication and division.

A further object is to provide an improved program control mechanism capable of effecting a series of successive calculations in a predetermined manner.

A further object is to automatically control the speed of operation of the machine in accordance with the type of calculation being performed.

The manner in which the above and other objects of the invention are accomplished will be readily understood on reference to the following specification when read in conjunction with the accompanying drawings wherein:

Fig. 1 is a plan view of a machine embodying a preferred form of the invention.

Fig. 2 is a partial longitudinal sectional view through the machine which, combined with Fig. 5, is taken along the line 2:5-2:5 of Fig. l and also line 2:5 2:5 of Fig. 30.

Fig. 2a is a plan view of one of the storage gear link brackets.

Fig. 3 is a side elevational view of the counter reversing mechanism which is located on the right hand side of the machine.

Fig. 4 is a sectional view of a centralizer pawl for the counter actuator, which pawl is located directly under and associated with the parts shown in Fig. 3.

Fig. 5 is a partial longitudinal sectional view through the machine and is taken along the rear portion of they line 2:52:5 of Fig. l.

Fig. 6 is a sectional view of the offset actuator racks taken on line 66 of Fig. 5.

Fig. 7 is a side view illustrating the rack and printer lock controls and part of the rack drive instrumentalities.

Fig. 8 is a side view illustrating the rack drive cams and cam follower.

Fig. 9 is a sectional side elevational view taken along the left-hand side of the machine and illustrating the motor and clutch controls.

Fig. 10 is a sectional side elevational view, taken along the left-hand side of the machine, illustrating part of the symbol printing controls which are further illustrated in Fig. 16 and Fig. 17.

Fig. 11 is a developed view of the symbol printing dial.

Fig. 12 is an elevational sectional view of the symbol printer idler gear.

Fig. 13 is a fragmentary side elevational view illustrating the overdraft controls for arresting operation of the machine.

Fig. 14 is a view of a sample tape having recorded thereon the factors and results of different types of computation performed by the machine.

Figs. 15 and lSa are coextensive, side elevational views, taken along the left-hand side of the machine, illustrating the accumulator positioning controls.

Fig. 16 is a sectional view taken along the line 16-46 of Fig. 10 showing in full lines the position of a bar for stopping the symbol rack in the X printing position and showing in broken lines the position of said bar in the printing position.

Fig. 17 is a View similar to Fig. 16 but showing the bar in the Q printing position.

Figs. 18 and 18a are coextensive elevational sectional views taken along the left-hand side of the machine illustrating the controls and cams used for obtaining either the quotient or product.

Fig. 19 is an elevational view of a ccntralizer ratchet 3 located behind and associated with the controls shown in Fig. 18.

Fig. is a more detailed view of certain parts also shown in Fig. 18.

Figs. 21, 22, and 23 are views of a lever operating pinwheel, also shown in Fig. 18, illustrating successively and respectively the controlled movement of a counter gear lever, a totalizer lever and a storage gear lever.

Fig. 24 is a sectional view taken along the right-hand side of the machine illustrating the storage, gear lowering controls and cams.

Fig. 25 is a sectional view of a key provided for setting the controls shown in both Figs. 24 and 3 and is taken along the line 2525 of Fig. 24.

Fig. 26 is a sectional view taken along the line 26-26 of Fig. 18.

Fig. 27 is a sectional elevational view, taken along the left-hand side of the machine, illustrating the controls effecting totalling and for clearing the keyboard.

Fig. 28 is a sectional fragmentary continuation of some of the totalling control parts shown in Fig. 27.

Fig. 29 is a sectional view taken along line 2929 of Fig. 2 illustrating a storage gear carrier chain.

Fig. 30 is a sectional view similar to Fig. 29 but taken along the line Edi-30 of Fig. 2.

Fig. 31 is a sectional plan view of the counter gear arrangement and is taken along the line 31-31 of Fig. 2.

Fig. 32 is a sectional plan view of the counters taken along the line 32-32 of Fig. 2.

Figs. 33 and 33:; are coextensive fragmentary side elevational views taken along the right-hand side of the machine illustrating a part of the printer suppressing mechanism and the motor-governor or speed control.

Fig. 4 is a sectional view taken along the line 34-34 of Fig. 33.

Fig. 35 is a sectional elevational view of a printer suppressor hook and is taken along the line 3535 of Fig. 34.

Fig. 36 is a sectional view taken along the line 3636 of Fig. 34.

Fig. 37 is a sectional view of the motor governor and related parts and is taken along the line 31-37 of Fig. 33.

Fig. 38 is a sectional view taken along the line 3338 of Fig. 37.

Fig. 39 is an enlarged view of the counter actuator reversing mechanism illustrated in Fig. 3.

Fig. 40 is a vertical sectional view taken along the line 40-4tl of Fig. 39.

Fig. 41 is a sectional plan view taken along the line 41-41 of Fig. 39.

Fig. 42 is a timing chart showing in graphical form the operation of various drive elements'of the machine.

General arrangement The particular machine illustrated as embodying the present invention is based partly on the we1l-known Clary adding machine, portions of which are disclosed and claimed in the following United States patents: No. 2,472,696 issued on June 7, 1949 to Edward P. Drake; No. 2,490,200 issued on December 6, 1949 to Robert E. Boyden; No. 2,492,263 issued on December 27, 1949 to Robert E. Boyden; No. 2,406,337 issued May 2, 1950 to Robert E. Boyden; and No. 2,5 83,810 issued on January 29, 1952 to Robert E. Boyden.

The present machine is motor driven under control of various motorized control bars and a multiply-divide control lever. The latter controls are arranged to be operated in various sequences in order to perform various desired calculations or combinations of such calculations, including addition, subtraction, division and multiplication.

A rotary drive shaft operated by the motor is provided to effect various machine functions, the drive shaft carrying various control cams for operating respective units of the machine. The drive shaft is effective under control of .4 a cyclic clutch to rotate one complete revolution for each machine cycle.

Referring in general to Fig. 1, an amount to be added or substracted, the dividend and the divisor in the case of a division calculations, and the mnltiplicand factor in the case of a multiplication calculation, is entered into the machine by depressing appropriate amount keys 10 of the machine keyboard.

In order to add an amount, one or the other of two add bars 11 and 12 is depressed, causing a cycle of operation machine to add the amount into an accumulator 13 (Fig. 5) and to print this factor on a paper strip 14. If the amount set up on the keys 10 is to be subtracted from an amount registered on the accumulator, a minus bar 15 is depressed.

i it is desired to print an amount set up on the keys but not to enter the same into the accumulator or other calculating units, a nonadd bar 16 is depressed. In order to add the same amount into the accumulator two or more times, a repeat bar 17 is depressed and held down until the requisite number of cycles, one for each addition, are made by the machine.

When it is desired to obtain the net'total amount registered by the accumulator, one or the other of two total bars 18 and 19 is depressed. This will print the total and clear the accumulator to zero. In the event, however, it is desired to obtain a subtotal, a subtotal bar 20 is depressed, causing the amount registered in the accumulator to be printed but retained in the accumulator.

in performing multiplication calculations, the multiplicand is entered into the amount keys 10 and a multiplicand entry key 21 is depressed, transferring the amount from the keys into a multiplicand-divisor storage unit 35 (Figs. 2, 29 and 30) to be described hereinafter. At this time the printing mechanism is actuated to record the multiplicand as at 22 (Fig. 14) on the recording tape 14- and the multiplier is entered into the machine by manipulation of a multiply-divide handle 23. The latter is slidable laterally of the machine into different denominational relationships relative to the amount keys and accumulator and is also rockable fore or aft of the machine to respectively effect add or subtract cycling. Thus, to obtain the product of a multiplicand factor by a multiplier factor of, for example, 45, indicated at 24, the handle 23 would first be shifted to its tens denominational position and then rocked rearwardly, from the operator, and held there until the machine has additively cycled four times. Thereafter, the handle would be shifted to the right one step to its units denominational position and rocked rearwardly to effect five additive cycles of the machine. During this operation the multiplier factor of 45 would be entered into a multiplier-quotient counter 25 and the product would be accumulated in the machine accumulator 13 (Fig. 5). However, the printing mechanism would be disabled.

In order to record the multiplier factor and the product as well as clear the machine for subsequent calculi.- tions, a product-quotient key 26 would be depressed, clearing the counter 25 and printing first, the multiplier factor on the tape at 24, directly below the multiplicand factor 22 (Fig. 14) as indicated and then printing the product directly below the multiplier factor as indicated at 27.

It should be noted that the multiplicand and multiplier factors, and the product, are all printed in decimal v correct relation and with the decimal points all in verticai alignment.

in division calculations, the dividend is first entered into the amount keys 1t) and thereafter entered into the rachine accumulator 13 by depression of one or the other of the add bars 11 and 12. Obviously, such factor is also printed on the tape 14, as for example, indicated at 23 (Fig. 14) and the keyboard automatically cleared. The divisor is now entered into the keyboard in its proper decimal relationship relative to the dividend and a divisor assaeee i. entry key is depressed, which effects transfer of the divisor into the multiplicand-divisor storage unit and printing of the divisor at 3?. Now, the handle 23 is moved laterally and normally to the left of its initial illustrated position until the divisor factor carried by the storage unit is properly aligned with the dividend registered on the accumulator. Thereupon, the handle 23 is rocked forward, toward the operator, to cause subtractive cyling of the machine. Such cycling will continue (providing the handle is held forward) until the re mainder for that denomination reaches a value lower than that of the divisor, at which time the machine automatically stops, indicating an overdrafted condition. The handle is thereafter rocked rearwardly to efifect a single additive corrective cycle and is then shifted one denomi- Keyboard The keyboard, including the amount keys 10 (Figs. 1, 2 and 5) is of the flexible type, and each amount key when depressed serves as a stop to limit movement of an aligned drive rack 34 which is effective, depending upon the type of calculation, to drive an associated element of the accumulator 13 to enter an amount therein corresponding to the dilferential movement of the rack, to set the printing mechanism to print such amount, and to set an aligned one of a series of multiplicand-divisor storage-gears 35.

The keyboard is divided into a plurality of rows of amount keys ranging in value from 1 to 9 and each key comprises a numbered key top 36 integral with a key stem 37. The latter key stems are guided for vertical movement in aligned slots formed in a top plate 38 and a bottom plate 39, the latter plates being suitably secured 4 together, and to machine frame plates.

The keys in each row are yieldably pressed upward by a tension spring 49 extending the length of the keyboard and suitably attached at opposite ends to the key plate 38. Each spring 40 rests on cross ribs 41 formed across slots 42 in the key plate and also extends through openings in the various key stems. Upon depression of a key, the adjacent portions of the associated spring db are stretched and extend through a slot 423.

Each key, when depressed, is latched in blocking posir tion by a locking bail 43 pivoted at opposite ends thereof on the vertical walls of the key plate 39 by trunnion bearings 4-4 and 45 (Figs. 2 and 5). For this purpose, each key stem has a cam lobe (not shown) formed thereon which, when the key is depressed, rocks the locking bail 43 laterally against the action of a spring extending between the top of each bail and the bottom of its adjacent bail. As the key reaches the bottom of its stroke the spring 46 returns the bail to a position over the top of the cam lobe, thereby latching the same.

The key stems 3'7 cooperate with respective ones of a series of shoulders l"! formed on the aligned racks 34 to control differential positioning of the latter. The various shoulders 47 are spaced apart distances slightly greater than the distances between the stems 37 so that depres sion of any key will permit forward movement of the associated rack 34 a number of increments equal to the value of such depressed key.

A zero block 48 extends downwardly from each of the locking bails 43, and When no key in the associated order is depressed, the bail 43 of that row will be spring held in an extreme inwardly rocked position wherein the zero block 48 lies directly in front of one of the shoulders 4'7 of the aligned rack, thereby preventing a substantial forward movement of this rack during subsequent operation of the machine. However, upon depression of a key, the locking bail will be held outward thereby sufficiently to retain the zero block 48 out of cooperative relation with its associated rack.

Referring in particular to Figs. 9 and 16, the stems of the various control bars such as 15, 16, i8 and 2t), and excepting keys 21, 26 and 34), are also slidably mounted in aligned slots formed in the key frame plates 33 and 39.

Drive The various units of the machine are driven by a rotatable drive shaft 49 (Figs. 6, 7, 8, 11, l3, 16, 22, 25, 26, 31 and 36) from an electric motor (not shown) under control of a cyclically operable clutch generally indicated at 5b (Figs. 9 and 13). The driven side of the clutch is attached to the shaft 4-9 and the clutch is controlled by a clutch dog 51 pivoted on a frame pin 52 and arranged to effect engagement of the clutch upon counterclockwise movement thereof away from the clutch. Disengagement of the clutch is effected by rocking the dog Sll clockwise into the position illustrated in Fig. 9.

Means are provided for yieldably transmitting a reciprocating motion to the various drive racks 34 from the shaft 4% during rotation of the latter. Referring to Fig. 8, a pair of juxtaposed complementary drive earns 52 and 53 are keyed on the shaft and cooperate with respective ones of a pair of rollers 54 and 55 mounted on a cam follower 56. The latter is pivoted on a stationary shaft 57 and is connected by a link 58 (see also Fig. 7) to an arm 59 suitably fastened on a rock shaft 6'9. A similar arm 61 (Fig. 2) is also fastened on the shaft 6% on the opposite side in the machine and both arms are bifurcated to embrace a rack drive shaft 62 mounted for fore and aft movement in an elongated slot formed in each of the machine side frames 172 and 173, one slot being shown at 63.

Referring to Fig. 2, each of the various drive racks 34 is supported at its forward end by the drive shaft 62, the latter being slidably embraced by a slot 65 in the rack. The rear end of each of the racks is provided with an elongated slot 66 (Fig. 5) which embraces the stationary shaft 57.

The slot 65 in each of the racks terminates at its closed end in opposed notches 67 normally engaged by rollers 68 carried by drive elements 69. The latter are rockably fitted in circumferential grooves formed in the shaft 62 and the adjacent drive elements 69 associated with each rack are spring urged in opposite directions by a tension spring 76 extending between the tails of the two elements to resiliently hold the rollers in the notches, thus forming a yieldable connection between the shaft 62 and the respective drive racks 34.

When, during forward movement of the shaft 62, as occurs during the first half of a machine cycle, each of the drive racks 34 is arrested due to striking against a depressed key stem or the associated zero block 48 or engagement of a nines stop shoulder 71 against a locking bail 72, the rollers 68 will ride out of the associated notches 67, thereby breaking the connection between the shaft 62 and the rack 34. The rollers will thereafter merely ride along the edges of the slot 65.

The racks 34 are returned to their zero or home positions during the latter half of each machine cycle by the cams 52 and 53, and means are provided for locking all of the various racks 34 in their zero positions at the completion of the machine cycle, as well as in their forwardly advanced positions during the midpoint or printing phase of a machine cycle. For this purpose, a series ofnotches 73 (Figs. 2 and 7) are formed on the under forward 

